System for a non-invasive online discrete measurement of phase levels in converters or pyrometallurgical furnaces

ABSTRACT

The present invention describes non-invasive online system for discrete measurements of phase levels in a converter or pyrometallurgical furnace in smelting and conversion processes, applying mechanical waves generated by a transducer placed transversally to an air blowing tuyere. Multiple transducers are placed in the direction of the cross axis or longitudinal axis of the phases plane and facing the different limiting zones between the different phases present inside the converter or pyrometallurgical furnace. A mechanical waves sensor or detector that receives the signal (echo pulses) reflected by the different limiting zones so as to determine the amplitude of the reflected signal that has a characteristic and different level for each phase, correlate the amplitude and determine the limiting zone of the phases that face the transducers.

FIELD OF APPLICATION

Present invention is related to the mining area, particularly to thepyrometallurgic area, specifically to the smelting and conversionprocess that occurs in furnaces and converters for production of refinedmetals when applying a field of mechanical waves in their interior.

PREVIOUS STATE OF THE ART

Within the mining processes, for example copper, a Converter, theTeniente Converter, used as the sole primary fusion system, has a systemallowing injection of dry concentrate through injecting tuyeres, therebyturning it into an autonomous system. The Teniente Converter is thesmelter's most important furnace since it defines its operationalcycles. Once the equipment's operational conditions have been definedregarding concentrate composition, the fusion capacity and kinetics ofthe process depend on flow and oxygen enrichment of air blown throughtuyeres.

The Teniente Converter (basically a horizontal cylinder with an outermantle or shell lined in its interior with refractory material ofdeterminate thickness within which 1250° C. chemical reactions occur,with dry concentrate injecting tuyeres, air blowing tuyeres and adrainage system placed at a certain height over ends of the Converter)is fed with a copper concentrate of approximately 28% copper content,injecting additionally through blowing tuyeres oxygen enriched air thatproduce a series of reactions that increase copper concentrate until itreaches 75% copper content

The Teniente Converter operation is based on heat generated by pyriticaldecomposition and sulphur oxidisation reactions and consists mainly ofmelting the solid raw materials that are fed into it, oxidise part ofthe load and obtain as a product two liquid phases, one rich in copper(white metal, of higher density) and another formed basically by oxidespresent in the bath (slag, of lesser density which remains over themetallic bath or white metal). Additionally, gases rich in sulphurdioxide are generated during the operation, which are sent to the acidplant for treatment. The Teniente Converter delivers as a final productwhite metal, slag and gases.

The white metal in the Teniente Converter is a liquid solution comprisedbasically by a mixture of copper and iron sulphides (Cu₂S and FeS) andcontains additionally a part of the impurities present in theconcentrates. Ellimination of these impurities occurs during thesubsequent conversion processes.

White metal's higher density in relation to slag causes the white metaldrops to descend through the bath to form a melted metal phase at thebottom of the furnace.

The melt's slag is formed by oxides fed to the converter; iron oxidesproduced by FeS oxidisation. Within the types considered the followingare found: Fayalite (2FeOSiO₂), Magnetite (Fe₃O₄) Silica (SiO₂),Allumina (Al₂O₃), calcium oxides (CaO), copper oxides (Cu₂O) and WhiteMetal (Cu₂S) trapped mechanically.

The desirable characteristics for slag are:

Should be miscible with the metal bath (white metal).

Low copper solubility.

Be fluid in order to minimise metal bath, concentrate and particleentrapment, and to allow adequate evacuation through the slag taphole.

The gas is formed basically by sulphur dioxide (SO₂), oxygen (O₂),Nitrogen (N₂) and water steam (H₂O).

Today, the process of obtaining white metal by Teniente Converter (CT)operation is subject to several problems whose solution has beenattempted by different means. Amongst these difficulties we can mentionthe lack of online measurement of levels of the different phases.Currently, this measurement is carried out with a rod that is insertedinto to the liquid metal thereby locating an operator over theconverter, with the inherent risks involved by this technique.Furthermore, another main problem in CT operation is the formation ofaccretions at ends of air blowing tuyeres that inject oxygen enrichedover the bath, since obstruction of airflow consequently decreases thechemical reactions within the converter, thereby decreasing its fusioncapacity. Additionally, the accretions adhere firmly to the refractorymaterial and part of this last is removed together with them, producingserious wear due to use of the tuyeres cleaning machine to eliminate theaccretions, ultimately producing internal ruptures evidenced at shortterm by the leakage of material to the exterior.

Furthermore, the slag entraps mechanically as well as chemically, inapproximately the same proportions, a significant copper content (around8%). This copper must be recovered subsequently in a slag treatmentfurnace with the greater cost involved for the complete process.

In the white metal phase chemical reactions occur due to oxygeninjection. These chemical reactions have their own kinetics given by thecontact surface between the bubbles and fluid metal that corresponds tothe interphase where the chemical reactions occur.

An increase in the chemical reactions means an increase in theproduction of desired metal in a fixed time period. This has its basisin kinetics, v=ke^(−E/k*T), where E is the activation energy. In thisway, the emission of mechanical, for example sonic, waves speeds up aspecific reaction, as it is able to supply a certain amount of energy(activation energy) and control it, meaning also that it is selective.

Specialized literature is aware of the fact that mechanical waves travelthrough solids as well as liquids and gases. Effectively, application ofultrasound in gases and metals in liquid state at high temperaturesbehaves like mechanical waves in general (See “Ultrasound Fundamentals”Jack Blitz, Alhambra Editorial, 1^(st) Spanish edition of 1969, pages31-33).

Because of this, present invention employs mechanic wave transmission ofcertain characteristics to maximise the physical-chemical coupling ofdifferent media. Additionally, using the transmission and reflectiveproperties of these mechanical waves that travel through different media(of different densities), it supplies an online and noninvasivemeasurement of parameters very important for an optimal operation of theprocess.

BRIEF DESCRIPTION OF THE INVENTION

Present invention consists of a system for generating mechanical waves,sonic as well as ultrasonic, of specific characteristics, transmitted tothe interior of a CT so as to maximise the physical-chemical coupling ofdifferent media. Additionally, using the transmission and reflectiveproperties of these mechanical waves that travel through different media(of varying densities), it supplies an online and non invasivemeasurement of parameters that are very important for an optimaloperation of a process.

So, a system has been implemented that increases the kinetics ofchemical reactions and in consequence, an increase in the production ofmetal.

This higher production of metal results from the higher efficiency ofoxygen reactions within the metal bath. The reaction capacity of oxygenper unit of volume of the metal bath per time unit in a converter orfurnace is measured through the SBSR (Specific Bath Smelting Rate), andis theoretically defined by:

SBSR=e·f·Qo/V _(Bath)

Where:

e=eficiency of oxygen consumption; f=oxygen enrichment; Qo=air flow; andV_(Bath)=bath volume.

The CT, under influence of the mechanical wave field (for example sonic,ultrasonic or infrasonic) that operates on the metal bath, slag andinjected air improves its fusion cycle in terms of an increase inproduction of metal bath (V_(Bath)), in presence of the mechanical wavefield.

Additionally there is a quicker homogenisation of the mixture, whichstabilises the temperature as well as the density of the mixture,allowing it to approach thermal equilibrium. On the other hand thesystem eliminates the accretions that form at the ends of the airblowing tuyeres, permitting a relatively constant flow of air to the CTreacting with the higher density fluid, thus extending the operationaltime of the CT by avoiding the interruption of the process to eliminatesaid accretions through use of the tuyere cleaning machine that usessharp tools to do the job.

As a result there is an increase in the useful life of the refractory aswell as the CT.

Certainly, another result is the ellimination, to some extent, of themetal entrapped in the slag. The selective attack of the mechanicalwaves on the different components of the slag inhibits the entrapment ofmetal by it, thus reducing the quantity of copper trapped mechanically,because said waves deliver enough energy to make the metal drops decant,reducing it greatly.

Another aim of present invention is to provide continuous and discreteon line measurements of temperature and phase levels.

In all industrial processes, the stabilisation of variables is essentialfor achieving a good process control. In pirometallurgical converters, agood control of the level of the white metal allows to decrease thecopper loss due to drag by the slag and also avoids foaming.

Moreover, a good control of the level of slag avoids unnecessary heatloss. Meaning that if we subject converters that contain in theirinterior fluids of different densities to mechanical waves, these willhave different propagation behaviours, and as it is known that theirreflection coefficient depends on the media they are transmittedthrough, the phase levels and the refractory wear can be determined inreal time or on line by relating these different reflectioncoefficients.

On line measurement of temperature of metal bath and slag and eventuallyof the temperature of the gaseous phase of the CT, allows a constantmonitoring of the system, so as to take the corresponding action for abetter use of the energy to increase fusion. Additionally it allows toavoid high fluctuations in temperature that produce thermal shock in therefractory. For this reason, the proposed measuring system submits theinformation directly to the Central Control System of the process inorder to execute the programmed operations for each situation.

In the same way, the system detects the white metal and slag levelswithin certain discrete ranges.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows the general schematic structure of a PirometallurgicalConverter, (Convertidor Teniente (Previous State of the Art)).

FIG. 2 shows a cross section of FIG. 1 (Previous State of the Art).

FIG. 3 corresponds to a first application of the invention to atransducer, set up to apply mechanical waves to travel longitudinallywith the airflow.

FIG. 4 corresponds to a second application of the invention to atransducer set up to apply mechanical waves to travel transversally withthe airflow.

FIG. 5 corresponds to a third application of the invention to atransducer set up to apply mechanical waves that propagate in a resonantchamber, so as to apply a large number of components of differentamplitudes of said waves with the airflow.

FIG. 6 is a graph of the SBSR (Specific Bath Smelting Rate) index, wherethe curves show this index with and without the application ofaforementioned waves. The different curves are parametrised depending onthe number of tuyeres that inject air into the metal bath.

FIG. 7 shows the invention system applied to the CT, in a schematic formand cross section.

FIG. 8 presents a block diagram of the invention, showing thetransducers with their respective sensors attached to the shell ormantle of the CT.

FIG. 9 shows a schematic figure of the circuit for the measurement ofthe time lapsed between the emission of the signal and reception of thedifferent echos of the signal, while doing the discrete and continuousmeasurement of phase levels.

FIG. 10 is an example of a descrete measurement of the phase levels.

FIG. 11 is an example of a continuous measurement of the phase levels.

DETAILED DESCRIPTION OF THE INVENTION

Present invention consists in a non-invasive system and method to applymechanical waves directly to a metal fluid at temperatures of around1250° C. Essentially it consists in a series of transducers thatgenerate mechanical waves that travel to the fluid metal through theoxygen-injecting tuyeres of a converter or pirometallurgical furnace.

This system consists in a means to generate electrical signals (1),transducers, for conversion from electric to mechanic signals (5) and amechanical connection (21) to ensure a perfect coupling with the mantleor shell (22) of the CT, through one of the blowing tuyeres (19) intowhich air is injected. (FIG. 7)

Additionally it has an analogical/digital interface (27), sonic sensors(6) and a unit (26) for processing signals and acquiring data for themonitoring of important variables of the process.

In FIG. 7 a schematic diagram shows the invention system (A) which hasin its interior a layout of sonic transducers (5), set up to agree withthe propagation direction and amplitudes of the mechanical waves (33) tobe applied to the metal bath (12) and slag (11). The breaking or removalof accretions (30) can also be seen, as well as the detachment of copperfrom the slag (35), whereas in the sector to which the mechanical waveshave not been applied, the copper trapped (38) in the slag has not beenable to come loose.

In FIG. 3 a transducer is set up to apply mechanical waves in alongitudinal direction to the airflow is described. For this purpose theair blowing tuyere has been placed in a side duct to form an angle equalto or less than 90° (α) with the airflow entrance and the transducer,remaining this last linearly and directly at the height of the oxygenenriched air inciding in the metal bath. Thus the mechanical wavestravel in a longitudianl direction with the airflow that reaches saidmetal bath.

FIG. 4 describes a second application of the transducer, set up to applymechanical waves that travel transversally with the airflow. This lastcan be done with a straight tuyere in the direction of the entrance ofthe airflow, and this time at least one transducer is placedtransversally to the air blowing tuyere (19). This ensures that themechanical waves travel in a transversal direction with the airflow thatreaches the metal bath.

FIG. 5 shows a third application of the invention, with a transducerwithin the resonant chamber which is part of the air blowing tuyere(19), forming a truncated cone attached to the shell of the CT in thetruncated or narrowest end. In this way the transducer emits themechanical waves which will resound first in the chamber, producingwaves with a variety of components of different amplitudes that travelwith the airflow to the interior of the CT.

The invention system (A) is coupled or joined to a pirometallurgicalconverter by one the blowing tuyeres (19) through a coupling piece (21)that ensures the mounting and a perfect seal between them. The couplingpiece (21) adheres to the shell (22) of the CT by mechanical means. Theshell is covered by refractory (29). The blowing tuyere (19) thatinjects air (32) enters the invention system and follows on into theinterior of the tuyere (19) till it reaches the metal fluid (12). Thewaves (33) that come from the transducer (5) are transmitted through theair (32) that circulates through the tuyere (19) till it reaches themetal fluid (12) where it gets incorporated producing physical-chemicalphenomena that allow to optimise the CT operation.

Another action developed by the invention, consists on preventing theformation of accretions in the blowing tuyeres and elliminating the wearof the refractory (29) resulting from the cleaning of said accretions.It is a well known fact that the highest refractory wear in the tuyeresarea (19) of the CT is due to the chemical reactivity that occurs inhead of the tuyere and to the effect of the sharp tools of the tuyerescleaning machine that uses a mechanical attack to clean the accretions.Avoiding the formation of accretions means a sharp decrease in the wearof the refractory (29). The ellimination of the refactory (20) wear anddecrease or ellimination of the mechanical attack of the tuyere cleaningmachine avoids interrupting the process due to filtrations in thetuyeres.

Another result of the use of the invention is to lower the copper (38)entrapped by the slag (11). The selective attack of the mechanical waves(33) over the different components of slag (11) makes the copper detach(35) from the slag (11) at least in its mechanical aspect, as theapplication of these waves delivers enough energy to decant the whitemetal drops trapped in the slag and reduce the Cu2O avoiding losses, andminimizing subsequent treatment to the slag (11) to extract its coppercontent.

Discrete Measurement of Phase Levels for a Pyrometallurgical Converter

The measurement is based on the determination of the level of areflected ultrasonic, sonic or infrasonic signal (echo pulses), in thelimiting zone between the different existing phases present in theinterior of the CT (from here on called interphases) needed to bemaintained between certain levels during the operation. To do thismeasurement, an ultrasonic, sonic or infrasonic transducer (5) is usedwith the capacity to generate a signal of intermediate power and detectthe reflected signal by at least one sensor (6), placed directly besideor integrated to, the transducer, or by one or more sensors placedaround the shell of the CT. Considering the density difference betweenthe phases (11, 12 and gases), the ultrasonic or sonic signal reflectedby the different interphases will have a different level characteristicof each phase. The measurement of the amplitude of the reflected signalindicates the phase present in front of the transducer at that moment,delivering thereby a discrete measurement of the position of theinterphase.

The resolution of this measurement is determined by the number oftransducers and the distances between them, but for the purpose ofhaving an alarm system that warns when the phase is at a certain level,only one transducer is needed.

An electronic circuit has been implemented capable of measuring the timelapsed between the echo pulses, which must be done in real time,integrated with the electronics that detect and preamplify the echoes.

The signal received is digitalised and processed by a DSP (DigitalSignal Processor). The processor determines the amplitude of the signaland thereby determines the phase facing each transducer.

The position of the transducers is known so the information thusobtained allows to determine, in a discrete range, the position of thedifferent interphases, o the alarm states defined (on the basis of theposition of the transducers). These discrete levels and alarm statevalues are stored finally in a outgoing memory that can be read througha serial RS-232, RS-485 or Ethernet TCP/IP communication port, which arethe most common communication standards of digital data in theindustrial equipment field.

Another objective, in consequence, is to make available the measurementin the RS-232, RS-485 and TCP/IP communication standards and allow theincorporation of these values to the instrumentation network of thepirometallurgical converter, so they can be available in a CentralizedControl System. This Centralized System must analyse the values obtainedagainst the control references stored and execute the previouslyprogrammed actions (operating registries, levels of different alarms,etc)

Continuous Measurement of Phase Levels for a Pirometallurgical Converter

The measurement is based on determination of the time of propagation ofa sonic, ultrasonic or infrasonic signal between the interphases thatseparate the different phases whose level must be known. To do thismeasurement a sonic, ultrasonic or infrasonic transducer (5) withcapacity to generate an intermediate power signal and detect thereflected signal (echo pulses). Considering the density differencebetween the phases, the ultrasonic signal is reflected by the differentinterphases, returning a fraction of the power to the transducer thatgenerated it. The measurement of the propagation time of the signal,between the moment in which it is emitted by the transducer and themoment in which the different echoes are received, considering aconstant propagation speed, allows us to determine the position of thedifferent interphases relative to the transducer.

An electronic circuit has been implemented capable of measuring the timelapsed between the echo pulses, which must be done in real time,intehrated with the electronics that detect an preamplify the echoes.This circuit has a crystal local oscillator that allows precisemeasurement of timelapsed between the emission of the signal and thereception of the different echoes of it.

The signal received is digitalised and processed by a DSP (DigitalSygnal Processor). The time measurements obtained thus are stored in anoutgoing memory that can be read through a serial RS-232, RS-485 orEthernet TCP/IP communication port, in the same manner as the discreterange measurement.

Likewise, if the on line temperature is known, corrective measures maybe taken that contribute to a better operation of the CT. The avoidanceof high fluctuations of temperature that provoke thermal shocks in therefractory allow to increase the CT operating time. As the mechanicalwaves are reflected with different amplitudes while crossing differentmedia, these differences allow to directly relate the temperatures ofthe different media. Therefore, the unit that acquires and treats thesignals (26), commands a power source (1) through an analogous/digitalinterface (27). The power source (1) controls a set of sonic transducers(5) attached to the shell (22) of a pirometallurgical converter (CT), bycoupling pieces (21). The ultrasonic or sonic transducers (5), excitedby the power source, emit mechanical waves (33) in the form of pulsesthat travel through the shell (22) and the refractory material (20). Themechanical waves (33) encounter the slag (11) or the metal bath (12),some are reflected and are received by sonic sensors (6), which in turnsend analogous signals back to the power source. These signals areamplified and sent by means of an analogous/digital interface (27) fromthe power source to the unit that acquires and processes the signals(26), where they are processed and transformed in digital data sent to acomputer (24) through a digital interface (25) between the computer (24)and the unit for acquisition and processing of signals (26). The datareceived by the computer can be observed through a procedure fordisplaying and monitoring said information.

The transducer of FIG. 3 can be mentioned as an example, operating at afrequency of 20 Khz. and a nominal power of 4 Kw, that applied to asituation like the one described in FIG. 7 allows to increase thereaction kinetics (34), detaching the copper entrapped (35) in the slag(11) and maintaining the air entrance (32) to the white metal (12) freeof accretions (39). On the other hand, the greater quantity of chemicalreactions that occur in the zone of direct application of ultrasonicwaves will generate a higher concentration in the outgoing gases(sulphur dioxide) allowing in turn a better performance of the acidplant that receives those outgoing gases.

What is claimed is:
 1. A system arranged to be operable with a furnacehaving mixtures of materials exhibiting different phases, the systemcomprising: a blowing tuyere generating an airflow, the tuyere having afurnace duct for transmitting the airflow to the furnace; an electricsignal generator for generating an electrical signal; at least onetransducer converting the electrical signal into mechanical waves, themechanical waves travelling in the furnace duct together with theairflow in a wave direction which is transversal to the airflowdirection along the furnace duct, the mechanical waves being transmittedto the furnace and being reflected by the materials according to theirdifferent phases to produce one or more reflected signals; at least onesensor detecting the one or more reflected signals and generating acorresponding one or more detected signal; and a first processingelement measuring the amplitude of the one or more detected signal todetermine the phase of the mixtures of materials producing the one ormore reflected signals.
 2. The system of claim 1, further comprising asecond processing element correlating amplitudes of different detectedsignals, to determine a relative position of the different phasesproducing the different reflected signals.
 3. The system of claim 1,further comprising: at least one amplifier, amplifying the one or moredetected signal to form one or more amplified detected signals; ananalog/digital interface digitizing the one or more amplified detectedsignals to form one or more digitized signals; and a data acquisitioncircuit acquiring the one or more digitized signals to form acquireddata, the acquired data being processed by the first processing element.4. The system of claim 1, further comprising a memory for storing valuesof the detected signals; and a display for showing the values.
 5. Thesystem of claim 1, wherein the sensor is placed beside or integratedwith the transducer.
 6. The system of claim 1, wherein the tuyerefurther comprises an entry duct.
 7. The system of claim 6, wherein theentry duct is placed at a 180° angle with the furnace duct.
 8. Thesystem of claim 1, further comprising coupling means connecting theelectric signal generator and the transducer with the furnace.
 9. Thesystem of claim 1, wherein the furnace is a converter.
 10. The system ofclaim 9, wherein the converter is a Teniente Converter (CT).
 11. Thesystem of claim 1, wherein the mixtures comprise a metal bath, a slagand gases.
 12. A method for determining phases exhibited by mixtures ofmaterials in a furnace, the method comprising: transmitting an airflowto the furnace in a duct along a first direction; generating anelectrical signal; converting the electrical signal into mechanicalwaves; transmitting the mechanical waves in the duct together with theairflow along a second direction transversal to the first direction tothe furnace, the mechanical waves being transmitted to the furnace andbeing reflected by the material according to their different phases toproduce one or more reflected signals; detecting the one or morereflected signals and generating a corresponding one or more detectedsignal; measuring the amplitude of the one or more detected signal todetermine the phase of the mixtures of material producing the one ormore reflected signal.
 13. The method of claim 12, further comprising:correlating amplitudes of different detected signals, to determine arelative position of the different phases producing the differentreflected signals.
 14. The method of claim 12, further comprising:associating detecting the one or more reflected signal with a level; andassociating the level with each determined phase of the materialsproducing the one or more reflected signal, to determine the position ofthe each determined phase.
 15. The method of claim 12, wherein saidmechanical waves are sonic waves.
 16. The method of claim 12, whereinsaid mechanical waves are ultrasonic waves.
 17. The method of claim 12,wherein said mechanical waves are infrasonic waves.
 18. The method ofclaim 12, wherein the furnace is a converter.
 19. The method of claim18, wherein the converter is a Teniente Converter (CT).
 20. The methodof claim 12, wherein the phases are a metal bath, a slag and gases.